Complex viscosity of dilute capsule suspensions: a numerical study

Q4 Engineering

Journal of Biomechanical Science and Engineering Pub Date : 2020-01-01 DOI:10.1299/jbse.20-00102

D. Matsunaga, Y. Imai

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引用次数: 2

Abstract

In this paper, we apply an oscillating shear flow to a dilute capsule suspension and report its viscoelastic properties. We analyze the complex viscosity under different capillary numbers and viscosity ratios, which is a viscosity contrast inside and outside the capsules. For all viscosity ratios, the real part of complex viscosity η ′ monotonically decreases with the frequency of the applied oscillating shear, while the imaginary part η ′′ shows the maximum value at an intermediate frequency. In general, the capsule with a larger viscosity ratio gives larger η ′ , while that of smaller viscosity ratio gives larger η ′′ . At high frequencies, the capsule that has higher (lower) inner viscosity contributes to increase (decrease) the viscosity of the solutions. In order to separately discuss the contributions of the membrane elasticity and internal fluid viscosity, we analyse the first term and second term of the particle stress tensor. The first term, which is called elastic stress in this paper, represents particle stress that arises from the capsule deformation. The amplitude of elastic stress is nearly constant at low frequencies, while it is inversely proportional to the applied frequency at high frequencies. The phase of elastic stress shifts from the shear to strain phases when the frequency increases. These tendencies of elastic stress do not depend on the viscosity ratio, and the qualitative trends are the same for all viscosity ratios. The second term, which is called viscous stress in this paper, represents particle stress that arises from the viscosity ratio, and the trend is drastically different by the viscosity ratio. The viscous stress contributes to increase (decrease) the viscosity and decrease (increase) the elasticity, when the capsule inner viscosity is higher (lower). Finally, we evaluate the effect of the capillary number. At low frequencies, both the capillary number and viscosity ratio are important factors for the rheology. On the other hand, the viscosity ratio becomes the only governing factor at high frequencies because the membrane elasticity has a negligible effect.

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稀胶囊悬浮液的复粘度:数值研究

在本文中，我们将振荡剪切流应用于稀释胶囊悬浮液，并报告了它的粘弹性特性。我们分析了不同毛细管数和粘度比下的复合粘度，这是胶囊内外的粘度对比。对于所有黏度比，复黏度η′的实部随振动剪切频率的增加而单调减小，而虚部η′在中频处达到最大值。一般来说，黏度比越大的胶囊η′越大，而黏度比越小的胶囊η′′越大。在高频率下，具有较高(较低)内粘度的胶囊有助于增加(降低)溶液的粘度。为了分别讨论膜弹性和内部流体粘度的贡献，我们分析了颗粒应力张量的第一项和第二项。第一项，本文称之为弹性应力，表示由囊体变形产生的颗粒应力。在低频时，弹性应力幅值几乎是恒定的，而在高频时，弹性应力幅值与施加频率成反比。随着频率的增加，弹性应力阶段由剪切阶段转变为应变阶段。这些弹性应力的趋势不依赖于黏度比，并且在所有黏度比下的定性趋势是相同的。第二项，本文称为粘性应力，表示由黏度比引起的颗粒应力，黏度比的变化趋势有很大不同。黏性应力对胶囊内黏度的增大(减小)和弹性的减小(增大)有促进作用。最后，对毛细管数的影响进行了评价。在低频率下，毛细管数和粘度比都是影响流变的重要因素。另一方面，在高频率下，粘度比成为唯一的控制因素，因为膜弹性的影响可以忽略不计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Biomechanical Science and Engineering Engineering-Biomedical Engineering

CiteScore

0.90

自引率

0.00%

发文量